Strength Testing - EXSC216 Study Guide PDF

Summary

This document provides a guide to strength testing methods, including their validity, reliability, and application in various sports and contexts. It covers different types of strength testing, equipment, and considerations for conducting these tests. The document discusses considerations for designing strength training programs, and includes norms for various sports.

Full Transcript

EXSC216
Strength Testing

1
Content

Strength & Strength Endurance Assessment
National Sports Science Quality Assurance program
NSSQA protocols

Validity & Reliability

Norms

Predictive equations

Scaling

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Why Is Assessing Strength Important?

Measures of strength strongly correlated with athletic performance
Discriminator of performance level in multiple sports
Optimise program design
Protective effect
Assess effectiveness of training program

Consider
absolute vs relative strength
Contraction mode specificity
maximal strength v power

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Discriminator
of
Performance
Level

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Strength Training for Endurance? Not just for
“Strength”
sports

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6
7
Part 2

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Testing

Time of day
Pre test training
Pre test nutrition & hydration
Exercise order
Explosive before max strength
Validity
Reliability
Calibration
Reporting

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Force-Velocity-Power

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Harris et al 2006
Type of test?

High force – low velocity
E.g., ???

Low force – high velocity
E.g., ???

Moderate force – moderate velocity
E.g., ???

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Specificity – What are you testing?

SAID Principle – Specific Adaptations to Imposed Demands
Monitoring impact of training

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 “Guide”
Relative Strength In Different Movements based off
1RMs

Baker ‐ ASCA Level 2 14
Validity and Reliability

Vital for data interpretation

Simple concepts, should be clearly understood

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Validity

How is it assessed?
r = 0.92

Compared to a ‘gold standard’.

Beep test example 

Ramsbottom, Brewer and Williams (1988)
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Reliability

How is it assessed?

Multiple, repeat tests in the same condition
Same day – intra-day reliability
Different day – inter-day reliability

Example of magnetic stimulation to the femoral nerve

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Test Validity:
Military Example – Jobs?
Infantry
Packs often > 40 kg
Marching with packs often > 5 km

Tank Crew
Frequent shell loading
~20 kg per shell

Clerk
Frequent desk operations

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Military Example – continued.

Biased toward lighter
individuals

No ‘strength’ assessment

Scaled for age and sex

Every job, same tests

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Military Example – new, proposed tests

Basic level for all soldiers
Clerks may need to be
deployed

Assess key capacities
E.g., strength

No scaling

“Level” based on job
demand
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Part 3

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What are we testing?

Maximum Dynamic Strength:

Maximum force that can be generated in a single effort against an
external resistance

Can be assessed in a number of ways

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Types of Strength Testing

Maximum Dynamic Strength
Isokinetic
Isometric
Isoinertial
Origins:
ísos = ‘equal’
kinetikos = ‘to move’.
metricos = ‘measure’
inertia = ‘resistance of
physical object’

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Why not isotonic?

What is it?
ísos = ‘equal’
tonic = ‘tension’

But:
Tension = changes through ROM
isoinertial = more accurate

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Brughelli & Cronin 2007
Equipment

Isometric testing
Force plate & immovable bar
Other measurement device

Isokinetic testing
Dynamometer

Isoinertial testing
Barbell/db
Weight plates

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Isokinetic Dynamometry

Constant angular velocity
Peak/average force
Popular clinically
Used in research
Assess asymmetry
Criticised for lack of performance
specificity but may be useful

Ham/Quad Ratio…

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Isometric Assessment

Characterised by muscle actions
that result in no change in joint
angle

Assess peak force & RFD

Require subjects to produce max
force against
Strain gauge
Cable tensiometer
Force platform
Load cells
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Isometric mid-thigh pull: A popular test

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Conducting an IMTP Test

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 Something’s
not right
IMTP Norms here…

Physiological Tests For Elite Athletes‐2nd Ed
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Other results:

Body Mass IMTP IMTP
Sport Sex
(kg) (N) (N.Kg-1)
Track Cycling
Male (n=1) 71.8 3488.9 48.6
(Olympic Medalist)

Motorbike Male (n=3) 72.9 3385.2 46.5

Weightlifting
Male (n=3) 89.3 4526.3 50.7
(AUS National)

Male (n=6) 78.8 3320.3 42.1
Tennis
(National/International)
Female (n=2) 65.3 2249 34.4

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Other Isometric Tests

Hip abduction & adduction
Shoulder (ASH/IR/ER)
Back extension
Grip strength
Groin Squeeze
Iso Push Up

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Isoinertial Testing

Constant gravitational load
throughout the movement

Repetition Maximum (RM) testing:
generally involve large muscle
mass movements for a specified
number of repetitions

Requires ability to handle
maximal loads

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Part 4

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Strength Testing Guidelines

General warm up/Stretch??

Specific warm up
40-60% specified RM for up to 10 reps
Minimum 2 min recovery
60-80% specified RM for max 5 reps
Minimum 2 min recovery
90% specified RM for max 3 reps
5 minute rest
Test sets

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Strength Testing Guidelines

Other considerations:

Experience
Strength
E.g., Lifter who squats 200 kg
Intensity/Reps 40% x 8 60% x 5 90% x 3 Test Set #1
Load (kg) 80 120 180 200?

Stronger lifters may require more warmup sets
Intensity/Reps 35% x 8 55% x 5 70% x 3 85% x 1 90% x 1 Test Set #1
Load (kg) 70 110 140 170 190 200
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Strength Testing Guidelines

Technical errors
Lowering and lifting in a
continuous manner
No > 3s pause between reps
Max 5 min recovery between sets
Minimum weight increments
dictated by
Equipment availability
Test movement
TE/CV%
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Strength Testing Challenges

Questions you should ask yourself:
Where do you start?
E.g., Specific loads? Exercises?

Safety?
Are they ready for this?

Why are you testing?
What’s the goal?
Is it actually necessary?

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What movements?

Bench press

Bench pull

Chin ups/Lat pulldown

Incline leg press

Single leg press

Squat

Others?

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Max Strength Reliability

1RM 1RM 1RM
Squat Bench Power
Press Clean
ICC 0.97 0.98 0.94

CV% 3.5% 2.8% 4.8%

Physiological Tests For Elite Athletes‐2nd Ed
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Determining Change

From previous:

What degree of change is required to be practically
important?
Individually
Group

Need to make an assessment of the magnitude of change and
consider the “noise” in the test

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Test Sensitivity

Ability of a test to detect smallest practically important change
Smallest worthwhile change calculated as:
0.5 CV% or 0.2 x between subj SD

Subject VJ (cm) Trial 1 VJ (cm) Trial 2

1 65 64

2 63 64

3 66 65

4 62 63

5 64 65

SD 1.58 0.84

X 0.2 0.32 0.17
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0.25
Individual Comparisons
Example
1RM Squat
CV:3.5%

First Score Second Score Change Rating

100kg 102.5 2.5kg stable

100kg 105 5.0kg higher

100kg 95 ‐5.0kg lower

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 Max Strength Norms
Source: Sport: n (Sex) Back Squat (RM)
Daniels et. al., 2019 Professional Rugby 21 (M) 199 ± 25 (3RM)
Freeston et. al., 2016 Well Trained 12 (M) 159 ± 49 (1RM)
Caia et. al., 2013 Elite AFL 18 (M) 131.4 ± 18.1 (1RM)
Caia et. al., 2013 Sub‐elite AFL 12 (M) 121.0 ± 16.7 (1RM)
Ooi et. al., 2009 Elite Malaysian Badminton 12 (M) 143.2±17.3 (1RM)
Ooi et. al., 2009 Sub‐elite Malaysian Badminton 8 (M) 129.9±14.1 (1RM)
Dridd et. al., 2015 Elite European Judo Players 5 (M) 179 ± 6 (1RM)
Dridd et. al., 2015 Sub‐elite European Judo Players 5 (M) 170 ± 5 (1RM)
AIS Basketball 10 (M) 115 ± 17 (3RM)
AIS Basketball 14 (F) 75 ± 14 (3RM)
AIS Rugby League 14 (M) 99 ± 24 (3RM)
Senior National Volleyball (90deg) 9 (M) 139 ± 30 (3RM)
Physiological Tests of
Junior National Volleyball (90deg) 7 (M) 115 ± 25 (3RM)
Elite Athletes (AIS,
AIS Netball (parallel) 12 (F) 67 ± 15 (3RM)
Tanner and Gore,
Elite Judo 14 (M) 121 ± 36 (3RM)
2013)
Elite Judo 11 (F) 92 ± 14 (3RM)
NTID Judo 16 (M) 86 ± 33 (3RM)
NTID Judo 14 (F) 66 ± 15 (3RM)
Senior Naitonal Rowing 10 (M) 137 ± 14 (3RM) 44
Part 5

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Predictions!?

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Prediction Equations

Not all subjects are capable of performing 1RM testing
Prediction equations allow estimation of 1RM from sub-
maximal repetitions
Numerous population specific equations
Multiple ways to predict

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Repetition Max Calculation

We know 1 RM, predict 6 RM:
Weight Lifted x Percent RM as decimal =

We know 8 RM, predict 1 RM:
Weight Lifted ÷ Percent RM as decimal =

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Reps to fatigue

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Velocity-based predictions

Using barbell velocity to:

Predict 1RM

Measuring barbell velocity
during concentric phase of
movement

Banyard et al (2017)

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Limitations with Velocity Tests?

Not all the research ends up with the same results

Banyard et al (2017) (
Relationship post-training intervention

Stable following training:
Muscular Endurance

Some sports require high force production for long durations
Generally:
Low load/No load (BW)
Absolute / Relative
strength endurance
Multi-joint movements
e.g., Chins, Leg Press, etc.

Issues?

http://s1.reutersmedia.net/resources/r/?m=02&d=20080811&t=2&i=5533069&w=780&fh=&fw=&ll=&pl=&sq=&r=2008‐ 55
08‐11T173320Z_01_PEK263334_RTRUKOP_0_PICTURE0
Part 6 - Final

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Big V Small

190 kg C + J 263.5 kg C + J
60 kg BW 163.5 kg BW
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Body Weight Considerations

Important issue in max strength 213 kg Snatch
assessment 263.5 kg C + J
If not taken into account then there can Sinclair: 480.25
be an over or underestimation of max
strength depending on the lift
External load favours heavier athletes
Body weight movements favour lighter 163.5 kg
athletes
Scaling relative to body weight
(strength/body mass) common but
result may not be equal for lifters of 152.5 kg Snatch
different mass (Cleather 2006) 190 kg C + J
Sinclair: 507.25
Other scales have been developed

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60 kg
Body Weight Correction

“Wilks” formula used in Powerlifting
Lift weight x body weight conversion factor
E.g. 69.3 kg male conversion factor is 0.7552

“Siff” formula for Olympic and other lifts

“Sinclair” formula used in Weightlifting and adjusted every
Olympic year based on World Record totals over previous
years
From Previous:

276.79 263.93 59
Coefficients

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Allometric Scaling

Scaling according to body mass attempts to account for
influence of muscle mass on performance
Known as “ratio” scaling (i.e. strength/BM)
Assumes a linear relationship between BM and performance
Allometric scaling involves raising BM to the power of 0.67
(BM0.67)
Based on theory that force & power increase with BM to the
power of 2/3

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